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Energy Landscape of Water and Ethanol on Silica Surfaces Di Wu, Xiaofeng Guo, Hui Sun, and Alexandra Navrotsky J. Phys. Chem. C, Just Accepted Manuscript • DOI: 10.1021/acs.jpcc.5b04271 • Publication Date (Web): 12 Jun 2015 Downloaded from http://pubs.acs.org on June 22, 2015
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The Journal of Physical Chemistry
Energy Landscape of Water and Ethanol on Silica Surfaces
Di Wu†, Xiaofeng Guo†,∥, Hui Sun‡ and Alexandra Navrotsky*†
†
Peter A. Rock Thermochemistry Laboratory and NEAT ORU, University of California, Davis, One Shields Avenue, Davis, CA 95616, USA
∥Earth
System Observations, Earth and Environmental Sciences Division, Los Alamos National Laboratory, Los Alamos, NM 87545, USA
‡
State Key Laboratory of Chemical Engineering, East China University of Science and Technology, Shanghai 200237, China
* Corresponding author E-mail addresses:
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Abstract Fundamental understanding of small molecule – silica surface interactions at their interfaces is essential for the scientific, technological and medical communities. We report direct enthalpy of adsorption (∆hads) measurements for ethanol and water vapor on porous silica glass (CPG-10), in both hydroxylated and dehydroxylated (hydrophobic) forms. The results suggest a spectrum of energetics as a function of coverage, stepwise for ethanol but continuous for water. The zero coverage enthalpy of adsorption for hydroxylated silica shows the most exothermic enthalpies for both water (-72.7 ± 3.1 kJ/mol water) and ethanol (-78.0 ± 1.9 kJ/mol ethanol). The water adsorption enthalpy becomes less exothermic gradually until reaching its only plateau (-20.7 ± 2.2 kJ/mol water) reflecting water clustering on a largely hydrophobic surface, while the enthalpy of ethanol adsorption profile presents two well separated plateaus, corresponding to strong chemisorption of ethanol on adsorbate-free silica surface (-66.4 ± 4.8 kJ/mol ethanol), and weak physisorption of ethanol on ethanol covered silica (-4.0 ± 1.6 kJ/mol ethanol). On the other hand, dehydroxylation leads to missing water – silica interactions, whereas the number of ethanol binding sites is not impacted. The isotherms and partial molar properties of adsorption suggest that water may only bind strongly onto the silanols (which are a minor species on silica glass), whereas ethanol can interact strongly with both silanols and the hydrophobic areas of the silica surface.
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Introduction Silica forms the basis for one of the most abundant and complex groups of inorganic structures, existing in the natural environment as minerals 1 and being produced synthetically as industrial materials
2,3
. Its various polymorphs may interact with small organic molecules and
water, and are extensively applied in many scientific and technological fields, ranging from classic heterogeneous catalysis
4-7
to recently developed organo-silica hybrid nanodevices
8,9
.
Organics encapsulated in silica nanoparticles are also employed to assist medical diagnoses and treatments 10, such as tumor targeted drug delivery 11,12. In all such applications, the energetics of adsorbate – surface binding is critical to function. On a larger scale, the thermodynamics of such interactions may also influence reactions at small molecule – mineral interfaces encountered under geological conditions, including in oil and natural gas recovery and CO2 sequestration 13-18. Despite the variety and complexity of organic – silica interactions, they seem to be largely governed by hydrophobicity/hydrophilicity and/or acidity/basicity performed on the structure of silica polymorphs
21-25
19,20
. Numerous studies were
and kinetics of surface binding
26,27
.
However, a systematic thermodynamic study of organic – silica interactions as functions of molecular coverage and surface hydrophobicity has not been reported. Nor has there been much direct comparison of the energetics of interaction of a given form of silica with water versus with simple organic molecules. Such differences in energetics form the basis for the competitive binding of water and organics to that surface, which in turn defines chemical, catalytic, biological, environmental, and geological reactivity. We previously performed a series of studies on organic – silica interactions using aqueous solution and solvent immersion calorimetry
28-31
. Here, we take a different approach.
Direct gas adsorption calorimetry 32, is employed to investigate the energetics of small organic
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molecule – silica binding. The experimental setup includes an accurate gas dosing system coupled with a Calvet twin microcalorimeter
32
, which enables precise and simultaneous
monitoring of the adsorption isotherm and associated heat effect for each small dose of adsorbing gas. Our initial water adsorption calorimetry studies revealed complex energetics as function of molecular coverage for nanoparticle surface hydration and suggested heterogeneous yet continuously distributed energetics of surface binding sites adsorption calorimetry to study CO2 capture sorbents
41,42
32-40
. Later, we extended gas
, in which stepwise energetics
corresponding to binding on different functional groups were revealed. Most recently, we expanded the experimental capability by using pure ethanol as the vapor source and studied its interaction with calcite nanoparticles. We revealed a complex energetic landscape, more complicated than that of the water – nanocalcite system
43
. The existence of a region of low
ethanol density between the first and second layer of adsorbed ethanol, suggested by molecular dynamics and spectroscopy
43-45
, was strongly supported by our calorimetric data by showing a
near zero differential adsorption enthalpy for ethanol molecules adsorbed after formation of the monolayer. These data strongly suggested discontinuous configuration of ethanol but continuity for water layers on nanocalcite. In the present work, we study the adsorption enthalpies of water and ethanol vapor on porous silica glass with both hydroxylated and hydrophobic surfaces. Our major goal is to understand the energetics of water and small organics on silica surface as functions of molecular coverage and hydrophobicity. Ethanol is selected to represent a small polar organic adsorbate, while water adsorption is performed for comparison. Controlled pore glass CPG-10, a synthetic, mesoporous silica with uniform surface and structural chemical properties is the adsorbent. The advantage of this particular silica material is that one can manipulate the degree of
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hydrophobicity by tailoring the number of hydroxyls through thermal treatment. Specifically, the adsorbed water molecules can be removed at 200 oC, releasing free hydroxyls (silanols). Further heating leads to dehydroxylation at 800 oC, resulting in a purely hydrophobic silica surface with only Si-O-Si bonds (siloxanes, see Figure 1a) 46. We believe water and ethanol adsorption
Figure 1. a) Schematics for dehydration process of silica surface. Gray, blue and orange spheres denote H, O and Si atoms, respectively. b) X-ray diffraction pattern. c) nitrogen adsorption isotherm (at -196 oC) of the CPG-10 silica glass and d) Temperature programmed desorption mass spectrometry (TPD-MS) profile of CPG-10 silica dehydration till 950 oC in flowing argon (40 cc/min).
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calorimetric measurements on both hydroxylated and dehydroxylated (hydrophobic) silica surfaces in a controlled manner will enhance our understanding of small molecule – silica interactions.
Experimental Methods Controlled pore silica glass (Millipore, CPG75C, Lot No. 01C009) was used as representative silica material (see Table 1 for its properties as provided by the manufacturer). Powder X-ray diffraction (XRD) diffraction was performed at room temperature on a Bruker AXS D8 Advance X-ray diffractometer (Cu Kα radiation, 40 kV, 40 mA, 5 to 90 ° two theta with a step size of 0.02 °at 1 s/step). A full nitrogen adsorption/desorption isotherm was measured at -196 oC using a Micromeritics ASAP 2020 instrument. Prior the isotherm measurement, the sample was degassed at 200 °C to remove any adsorbed species. The Brunauer–Emmett–Teller (BET) equation 47 was applied to obtain specific surface area. Table 1. Material properties of CPG-10 silica
Millipore This study
Specific surface area (m2/g) 197 192
Pore (nm) 8.1 7.8
diameter Pore size distribution (±%) 8.9 8.6
Pore volume(cm3/g) 0.49 0.48
Temperature programmed desorption mass spectrometry (TPD-MS) was performed using a Netzsch STA 449 coupled with a Micromeritics Cirrus 2 quadrupole mass spectrometry to reveal the distribution of surface water species. About 20 mg of sample was placed in a platinum crucible and heated from 30 to 950 oC at 10 °C/min in argon flow (40 mL/min). The evolved gas was introduced into the ionization chamber of mass spectrometer. The TG and MS signals (H2O, m/z = 18) were corrected using the reference baselines collected by performing runs without sample under the same experimental conditions. 6 ACS Paragon Plus Environment
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The water/ethanol adsorption system includes a Calvet-type microcalorimeter (Setaram Sensys), which is coupled to a gas adsorption analyzer (Micromeritics ASAP 2020). About 100 mg of sample was placed into one side of a custom designed silica forked tube, the other side of which was kept empty as a reference. Then the tube was inserted into the twin chambers of the calorimeter and connected to the analysis port of the gas adsorption analyzer. The sample was subjected to degas at elevated temperature under vacuum (
